NL8104101A - PAL COMB FILTER. - Google Patents

Description

* i

* PHN 10.152 1 y, fr, 3 T S-J

N.V. Philips' Incandescent lamp factories in Eindhoven. L --- PAL comb filter. | 4 SEP 1981 ^

The invention relates to a PAL comb filter comprising a first and a second chain, input means for supplying a PAL color signal to both chains, a delay network for delaying the PAL color signal in the first chain with respect to the PAL color signal in the other chain, and a signal combination circuit for combining the PAL color signal in the second chain with the correct mutual polarity and the PAL color signal delayed in the first chain, such that it is effected by that combination resulting signal again is a PAL color signal. In this context, a PAL-10 color signal is understood to mean a color signal in which the phase of one of the two squared modulated color components changes the other line. The term "PAL color signal" is thus not limited to, inter alia, the television-standardized carrier frequency of 4.433 MHz.

Such a comb filter can be used for filtering PAL color signals in various video systems, such as for instance television, video cassette recorders and video plate systems. Particularly in recording and playback systems in which the video signals are recorded or recorded in parallel tracks, such a PAL comb filter is used for suppression of color crosstalk from neighboring tracks. A drawback of the known PAL comb flashes is that they require a delay network with a time delay equal to the duration of two lines of the video image, which, among other things, gives rise to a vertical shift of the color image relative to the brightness image and a decrease in vertical resolution, which effects are particularly disadvantageous in video recording, where video magnetic tapes are copied. A solution to this problem is to convert the PAL color signal into a quasi-NTSC color signal am and reset it after filtering, so that a delay network 30 with a time delay equal to the duration of a line of the video image suffices. turn into. The drawback of this is that the video signal must be switched line-alarming, which can lead to phase errors in the obtained PAL color signal, resulting in color disturbances.

8104101 <* »PHN 10.152 2. . A further drawback is that due to this quasi-PAL-NISC conversion in that part of the video system where the quasi-NTSC signal is processed, the advantages of PA freoding are lacking.

The object of the invention is a PAL comb filter that provides less color-5 shift and a higher resolving power than the known PAL comb filter without carrying out a quasi PAL-NTSC conversion.

The invention is characterized for this purpose in that the delay network has a time delay such that the PAL color signal in the first chain corresponds to the line corresponding to a video image. 10 is delayed relative to the PAL color signal in the second chain, and that PAL phase inversion means are included for the inverter and the phase phase of the signal in either chain.

When recording video signals in parallel tracks qp 15, a record carrier can overcome color errors when reproduced by scanning the record carrier over the tracks, such as in the playback mode in which the program is played back at an accelerated rate, the PAL color signal at a periodic additional PAL phase inversion to make the PAL phase equal to each other in adjacent track sections. In normal playback mode, as well as in systems where the PAL phase changes from track to track in the accelerated state, the PAL color signal must then be subject to corresponding PAL phase inversions. To this end, the PAL phase comb filter according to the invention can be further characterized in that the PAL phase inversion means are designed to be controllable, such that the PAL phase inversion takes place on command of a control signal or in the first 6f in the second chain. . By moving the PAL phase inversion from one chain to another, an additional PAL phase inversion occurs in the output signal while the comb filtering operation is not affected.

A further feature of this embodiment is that the PAL phase inversion means cravat a first switchable PAL phase inverter included in the first chain and a second switchable PAL phase inverter included in the second chain, wherein control means are present for alternately switching on one of the two PAL phase inverters at the command of the control signal. A PAL comb filter for use in a PAL video system where the PAL color signal with a first carrier frequency 81 0 41 G1> s PHN 10.152 3 is transformed into a PAL color signal with a second carrier frequency, can be further characterized in that the PAL phase inverse means frequency mixing means for mixing the PAL color signal with a first carrier frequency with a signal with a frequency equal to the scm of the first and second carrier frequencies such that mixing occurs in both chains of the comb filter. For use in a PAL video system where the PAL color signal with a first carrier frequency is transformed into a PAL color signal with a second carrier frequency, the PAL camp liter can be further characterized in terms of introducer and additional PAL phase inversions in that the first switchable PAL phase inverter a first mixing stage and the second switchable PAL phase inverter cravat a second mixing stage for the transformer and the PAL color signal from the first carrier frequency to the second carrier frequency, and that the control means comprise a mixing signal generator for supplying a first mixing signal with a frequency equal to the scm of the first and second carrier frequency and a second mixing signal with a frequency equal to the difference of the first and second carrier frequency cravat, and further cravat switchable by said control signal for feeding the ee in a first position first mixing signal to the first mixing stage and the second mixing signal to the second mixing stage and in a second position supplying the second mixing signal to the first mixing stage and the first mixing signal to the second mixing stage. Mixing with the scm 25 of red-colored frequencies thereby transforms the PAL color signal to the second carrier frequency with inversion of the PAL phase, while mixing with the difference of the frequencies gives transformation without inversion of the PAL phase. In this manner, the comb filtering operation combines the additional PAL phase inversion and the transformation of the PAL color carrier in a very simple manner.

This advantageous embodiment can be further characterized in that between the mixing signal generator and the first mixing stage a first mixing stage is a first switchable mixing signal phase inverter and between the mixing signal generator and the second mixing stage is a second switchable mixing signal phase inverter. to make the carrier phase of the PAL color signal reversible with the second carrier frequency. This makes it easy to change the polarity 8104101 i '* PHN 10.152 4. of the PAL color signal carrier achieves what is necessary to nullify polarity changes introduced during recording to reduce the effects of color crosstalk.

In order to also be able to apply this embodiment in a PAL comb filter for use in a video system in which the PAL color signal with the second carrier frequency is transformed into a PAL color signal with the first carrier frequency to record the video signals, this embodiment can further characterized in that an output for taking the PAL-10 color signal at the second carrier frequency is connected through an bandpass filter tuned to the second carrier frequency to an output of the second mixer.

The invention will be further elucidated with reference to the drawing, in which: Figure 1 shows a known comb filter for PAL colors and signals with the principle diagram in Figure 1A and a diagram explaining the operation of the filter in Figure 1B,

Figure 2 shows a comb filter according to the invention with in Figure 2A the principle diagram of that comb filter and in Figure 2B 20 a diagram explaining the operation of that comb filter,

Figure 3 shows an embodiment of a PAL-phase inverter, Figure 4 shows some trace patterns that may occur when recording video images, with the PAL phase indicated therein, Figure 5 shows the trace patterns of Figure 4 in accordance with 25 'trace patterns after introduction of additional PAL phase inversions, shows,

Figure 6 shows an embodiment of a comb filter according to the invention, in which the PAL phase of the output signal can change,

Figure 7 shows corresponding track patterns with the track patterns of Figure 4 with polarity changes of the color carrier indicated therein,

Figure 8 shows a preferred embodiment of a PAL color processing circuit incorporating a PAL comb filter according to the invention, Figure 9 shows some trace patterns of Figure 6, however, with other H alignments n,

Figure 1 shows a known comb filter for PAL color and signals with the principle diagram in Figure 1A and a diagram in Figure 1B 8104101

Ir. * PHN 10.152 5 explanation of the operation of the filter.

A PAL color signal I (Fig. 1B) is presented as a system of three signals represented by colors, namely the color components RY and BY and the color burst CB, which components 5 on a carrier wave with a frequency f <, in particular 4.433 MHz , are modulated. In the other line, with a PAL color signal, the component R-Y, as well as the color burst signal, are inverted in phase with respect to the phase of component B-Y.

The operation of a comb filter is based on favoring 10 periodic components in the signal by adding that signal to the signal delayed over time according to the periodicity of that signal. Due to the PAL phase inversion, the PAL signal has a periodicity equal to two line times H on the other line.

The comb filter according to figure 1 has an input 5 to which the PAL color signal is applied. Via a time delay network 1 with time delay delay "C = 2H, the signal delayed by two line times is applied to an adder circuit 2, to which the undelayed signal is also applied. The time delay 2H is adapted to the signal frequency such that the add carriers exactly in phase or subtract exactly in counter phase The output signal I = 1, + 1 can be decreased from an output 6.

It can be seen from FIG. 1B that the PAL color signal and the PAL color signal It_2H delayed by two line times are in phase PAL phase-wise, so that the sum signal I again forms a PAL color signal.

The filter of Figure 1 can be used to suppress color noise as well as suppress the crosstalk of 30 color signals from the neighboring tracks of a scanned track in video recorders. A drawback of this filter is the time delay over 2 line times H, which leads to a reduction of the vertical resolving power of the color image, as well as to a vertical shift of the color image, which effects become particularly disturbing in those cases where repeated operations with a comb filter, such as that used repeatedly when copying videotape bands.

These drawbacks become noticeable by using a comb filter with a delay time equal to a line time H.

8104101 ΡΗΝ 10.152 6 ί

Figure 2 shows a comb filter according to the invention with in Figure 2A the basic diagram of that comb filter and in Figure 2B some diagrams to explain the operation of that comb filter.

The PAL color signal 5 It is applied to the input 5 of the comb filter. This is applied to an input 7 of a PAL phase inverter 3. The signal It is inverted in terms of PAL phase at an output 8 thereof. This PAL phase inversion means that continuously, i.e. for all lines, the phase of the (R-Y) component as well as the color burst CB is inverted with respect to the (B-Y) -10 component. This signal is passed through a delay network 4 with a delay time ^ = 1H (H = line time), making the color signal delayed by a line time and PAL phase inverted available. In an adder circuit 2, this signal It <_H is added to the original color signal and the signal Ιο = ΐ ^ is obtained at output 6, which addition of the carriers the signals It and are exactly in phase by adjusting the time delay L.

It is clear from Figure 2B that the qual PAL phase inverted signal after a delay over a line time again corresponds in terms of the PAL phase to the original color signal, so that by adding again a PAL color signal IQ is obtained, whereby, although the PAL color signal lt is periodically is equal to two line times over a period, yet with a delay network with a delay equal to a line time one. comb filtering action 25 is obtained. With the circuit according to figure 2 it can be noted that the PAL phase inverter 3 can also be included after the delay network 4 as well as in the circuit other than that in which the delay network 4 is included.

Figure 3 shows an exemplary embodiment of a PAL phase 30 inverter. This includes an input 7 to which the PAL color signal is added. Input 7 is connected to an input of a mixing stage 16 and just a color burst port 9 to which an impulse signal indicating the occurrence of a color burst is supplied via an input 10. A voltage-controlled oscillator 13, which is tuned to a frequency 35f with the frequency of the color subcarrier with angular frequency wg, supplies a signal to a two-divider 12. A phase comparison circuit 11 compares the phase of the color burst with the frequency-divided output signal. of oscillator 13 and 8104101 PHN 10.152 7 ... adjusts oscillator 13 via low-pass fliter 14 so that the oscillator 13 is phase-locked to the color burst. The output signal OSC of oscillator 13 is applied to the mixing stage 16 via bandpass filter 15 and mixed with the color signal It <The output signal of mixing stage 16 is supplied to output 8 via bandpass filter 17. This output signal is the PAL phase inverted color signal, which follows from the following calculation:

For the PAL color signal applies:

It = (B-Y) sin (wst) + (R-Y) cos (Wgt) 10 Here, the + sign of the (R-Y) component indicates both PAL phases.

For the oscillator signal OSC holds: OSC = -2 cos (2wst)

Here, the polarity and airplitude are chosen so that the (B-Y) component with gain +1 appears at output 8. For the output signal 1 ^ = 1 ^ X OSC, after filtering out the components with angular frequency wnrdt is found: I. = (B-Y) sin (w t) + (R-Y) cos (w t)

U S S

Here the (R-Y) component is inverted in character.

The same calculation holds for the color burst -sin (wst + - ~) 20 which transforms to -sin (w t + ~~).

s 4

The comb fliter for PAL color signals with a PAL phase inverter represented on the basis of figure 2 can very well be fitted into the PAL color signal processing circuit of a video recorder, which is in accordance with the following considerations, which ultimately become the preferred embodiment according to figure 8. will be clarified.

In the case of a video recorder of the type where the tracks, because the magnetic tape has been screwed helically in a head drum, lie obliquely to the longitudinal direction of the tape, the starting points of the tracks change from track to track. The ratio of this offset to the track length corresponding to just one line time H of the video signal is called the H alignment n. The sign of this factor n is by definition negative if the tape transport direction (V in Figures 4, 5, 7 and 9) is opposite to the direction of movement of the video heads (V in Figures 4, 5, 7 and 9).

A first measure with regard to the track pattern is to select the H alignment n such that the line synchronization 8104101.

i * - PHN 10.152 8 ------ pulses in alignments perpendicular to the tracks are aligned, which is especially important, for example, to avoid time-base errors in fast forward or reverse playback of the video images. In the case of a two-head recorder with two heads, the head slits of which tap at an angle to one another, it is therefore the case that the line synchronization pulses of all the even-numbered tracks as well as all odd-numbered tracks are aligned. However, in order to avoid adverse effects due to crosstalk, it is advantageous, however, to align the line synchronization pulses of all tracks.

10 This alignment can be achieved without using delay networks when the H alignment n is an integer multiple of + ½ or -½ (with a two-head recorder). Figures 4a, 4b and 4c show in this case the trace pattern for n = -1, n = -2 and n = -3. It is noted here that for a positive or negative integer value of n 15 this is achieved by making the tracks A and C half a line longer than the tracks B and D. This creates a video image of 625 lines, if equally over two tracks. distributed, would result in an incomplete number of lines per track, so that the H-alignment would alternately be n = 0.5 and n = 1.5 (in the case of Figure 4a) - which in itself is not objectionable to be. However, with the track patterns shown, the 313rd line is always entirely recorded in the track associated with the first frame of the video image, which can be easily achieved by a suitably chosen placement of the heads on the head disk,

When in the track patterns according to figure 4 the PAL phase 25 of lines perpendicular to the track direction is looked at - which PAL phase is indicated by arrows corresponding to the relevant PAL phase in figure 4 - then the PAL phases in directions perpendicular to the track direction out of alignment. This causes serious color disturbances in the displayed video image when the heads run obliquely over the tracks during accelerated reproduction. As with the alignment of the line synchronization pulses, it is also important here to align the PA1 phases of all tracks. As with the alignment of the line synchronization pulses, two-head video recorders whose head gaps are angled relative to one another suffice with the alignment of the even tracks and the odd tracks mutually.

However, it is also useful here to align all tracks.

One possibility to achieve this is to delay the color signals associated with just 8104101 PHN 10,152 9 selected, which, however, creates drawbacks such as color shift. A more attractive solution is to invert the PAL phase of the color signals associated with correctly selected lines (which is easy to combine with the PAL phase inversion 5 for the comb filter as will be described with reference to Figure 8). For a definition of the tracks as shown in figure 4 these are for n = + 1, +3, +5 ... the tracks C and D and for n = 0, +2, +4 ... the tracks B and C. The resulting trace patterns 10 corresponding to the trace patterns according to FIGS. 4a, 4b and 4c are shown in FIGS. 5a, 5b and 5c, respectively, in which the PAL phase inverted traces are indicated by an asterisk. It is hereby noted that this PAL phase inversion must be nullified during reproduction. Another possibility in the case of a track pattern according to Fig. 4 not to be hindered by the alternating PAL phase 15 during reproduction with the head running obliquely over the tracks, such as during accelerated reproduction, is the detection of trace exchange and, if necessary, detected track change additionally invert the PAL phase of the read signal. In this case, as well as when using the recording method described with reference to Figure 5, it is necessary to additionally invert the PAL phase of the signals from certain tracks. This can be done very advantageously in combination with the PAL phase inversion for comb filtering. In addition to the preferred embodiment of Figure 8, this can also be done, for example, with the circuit shown in Figure 6. This circuit 25 is similar to that of FIG. 2a where a cross switch 51 is inserted between the PAL phase inverter 3 and the delay network 4. Depending on the position of that switch 51, PAL-phase inversion plants will then find plants in the chain with the time-delay network 4 or in the chain that is parallel thereto. Changing this position results in an additional PAL-phase inversion for output signal at output 6. .

Another problem with video recorders where the tracks are written close together is the crosstalk of the color signals.

A known method to solve this problem is to invert the phases of the color subcarrier according to a suitably chosen pattern, so that the crosstalk components largely cancel each other out in the comb filter. When using the comb filter according to the invention, this assumes a delay time in the comb filter equal to 8104101 / * · PHN 10.152 10 ------ to a line time H. A suitable inversion pattern for the color subcarrier with the trace patterns according to figures 4a, 4b and 4c, figures 7a, 7b and 7c show in which the lines of which the color subcarrier is phase inverted are indicated with an asterisk. The operation is 5 as follows:

If a head senses the line indicated by 18 in figure 7a, this is line number 317, then in the comb filter (figure 2a) the color signals of lines 316 and 317 of that track B add, while the cross-talk components of lines 4 and 5 of the adjacent track B as well as the crosstalk-10 components of lines 2 and 3 of adjacent track C largely cancel each other. The same situation occurs when line 19 of track D is sampled, whereby, taking into account the nullification of the phase, inversion of the subcarrier of line 2 of that track C during reproduction, in which case also the cross-talkers of the lines 316 resp. In addition, 314 of the adjacent tracks B and D are inverted, the crosstalk components of lines 316 and 317 of adjacent track B as well as the crosstalk components of lines 314 and 315 of adjacent track D largely cancel each other.

Figure 8 shows a preferred embodiment of a PAL color-20 processing circuit incorporating the foregoing. The situations during playback are indicated with (PB) and the situations during recording with (PEC). The various switches other than switch 38 are shown in the display position. The operation during reproduction is as follows: In the comb filter in the embodiment according to figure 8 (compared to the embodiment according to figure 2a) the function of the PAIR phase inverter (3 in figure 2a) is combined with that of an auxiliary carrier with frequency f Mixing the color signal to the subcarrier with frequency f in mixing stage 21. in the other circuit of the comb filter w30 a mixing stage 22 is also included. From these mixing stages 21 and 22 the desired mixing products with bandpass flashes 20 and 23, which are tuned to the frequency f, are separated. The desired mixing product of mixing stage 21 is delayed with delay network 4 by a line time H and then added in adding network 2 to the desired mixing product of mixing stage 22 so that the filtered PAL color signal appears at output 6 of the comb filter, The desired PAL phase inversion as well as the inversion of the phase of the subcarrier cos wst is effected in both mixing stages 21 and 22 by suitable manipulations with the msng carriers for those mixers, which will be further explained.

The inputs of the stage stages 21 and 22 are connected to an input 29 via a common input 50, a switch 27, which is in the position shown in the drawing, and a frequency-matched bandpass filter 28. During input (PB), the PAL color signal separated from a video signal 26a - which is alternated with a second head with each second head every second scanned track - is supplied to said input 29.

In the video recorder system for which the circuit according to figure 8 is intended, this PAL color signal is a modulated subcarrier wave with a frequency f, in the case of 750 kHz, for example. The output signal at output 6 of the comb filter, being a modulated carrier with frequency f, in particular 4.433 Mhz, is further processed in the usual manner and finally presented to a television set 25.

In the mixing stages 21 and 22, respectively, the received EAL color signal modulated with a carrier wave with frequency f., Depending on the position of switch 38, is mixed with a carrier wave 20 with frequency fs + f ^ respectively f or with a carrier wave with frequency f. fs + f ^, respectively. The result is as follows:

The PAL color signal received at input 50 can be expressed as: (BY) sin w ^ t + (RY) cos wJ: (1) 25 Mixing with -cos (w + w.) T gives (BY) sin wt + ( RY) cos w ^ t) (2)

Mixing with -fcos (ws + w ^) t gives - £ (B-Y) sin w ^ t + (R-Y) cos w ^ t J (3) mixing with cos (w t-w.t) gives

3 X

30 (B-Y) sin w t + (R-Y) cos w t (4)

Mixing with -cos (wst-w ^ t) gives - f (B-Y) sin wgt + (R-Y) cos wgt J (5)

The preceding shows that mixing with a signal with the difference frequency f-f. the original PAL color signal modally 35 with a carrier at frequency f and mixing with a signal of the scanning frequency f + f also inverts the PAX phase of the original PAL color signal. It should be noted here that, for the sake of simplicity, the color burst CB sin (w / t + ~~) is not included in the calculation 8104101 PHN 10.152 12. The Inversion phase can also be encountered for this.

Furthermore, the foregoing shows that polarity change of the carrier mix induces a phase inversion of the subcarrier, i.e., a polarity change of the modulated PAL color signal.

Thus, a PAL phase inversion (see Figures 5 and 6 and description) and an inversion of the subcarrier phase (Figure 7 and description) can be effected in this way. To this end, the circuit shown in Figure 8 includes a mixing stage 44, by which, by mixing a signal with frequency f., Originating from phase-locked loop 43, and a signal with frequency fg, - originating from oscillator 45, the scff, fg + f ^ and the difference frequency f -f. which sum and difference frequencies are separated with filters 41 and 42.

With controllable phase shifters 40a and 40b, the sign of the signals thus generated with frequencies f + f. and f -f. are inverted and with switch 38 the mixing signals for mixing stages 21 and 22 can be exchanged. switch 38 is controlled such that the PAL phase inversion induced for PAL phase alignment (see FIG. 5 and description) induced upon recording is canceled. It is also possible in the absence of PAL phase alignment on command of a track change detector to ensure, among other things, accelerated reproduction with the aid of switch 38, an undisturbed PAL phase segregation. If it is assumed that the PAL color signal has been recorded in accordance with the pattern of Figure 5a, then the PAL phase must be inverted each time the tracks C and D are read, in this embodiment in both parallel chains of the KAM filter, i.e. In both mixing stages 21 and 22. In addition, the signaled must be continuously inverted in έβη of both chains, in this embodiment in mixing stage 21, for the comb filtering operation (see figure 2 and description), additional gua PAL phase, on which both conditions 30 has been satisfied by supplying the mixing signal with the sum regulation (f + f.) To mixer 21 during the reading of tracks A and B and the mixing signal with difference frequency (f-f.) To mixer 22, and by - starting from the data that twice inversion, namely once for comb filter operation and once for the purpose of canceling the PAL phase inversion when tracks C and D are recorded, is the same as non-invert - during and the scanning of tracks C and D the mixing signal with the scmf regulation (f + f.) of mixer 22 and

S X

Add the mixing signal with the differential frequency (f-f.) to mixer 21 x 8104101 PHN 10.152 13.

Phase inverters 40a and 40b, if the one according to the pattern of figure 7 is recorded, must switch during scanning of the tracks A and C at the beginning of each line, while phase inverter 40a must be switched on during 5 scanning of the tracks B and D (In the case of merging with the scanning frequency, that the inverted phase mixing signal must be supplied in order to obtain a PAL phase inverted signal without the phase of the subcarrier inverting - see under expression 2: "Mixing with -cos (w + w. ) t ".

In order to properly operate switch 38 and phase inverters 40a and 40b, the circuit according to figure 7 comprises an input 51 to which, for example, the video signal derived from an M demodulator 33 is supplied, the horizontal signal of which is switched by means of an impulse separation circuit 35. and vertical synchronization pulses are separated which appear at an output 48 and 47, respectively. The vertical synchronization pulses at output 47, which occur once per track when drawing a television frame per track, synchronizer and via a logic circuit 37, for example a counter, switching switch 38, circuit 37 being arranged such that the desired switching pattern from switch 38 is obtained. The horizontal synchronization pulses at output 48, as well as the vertical synchronization pulses at output 47 synchronize via a logic circuit 39, for example built up of counters, the switching of phase inverters 40a and 40b according to the desired pattern.

The horizontal synchronization pulses at output 48 of pulse separation circuit 35 are additionally applied to the phase-locked loop 43 to generate a signal of frequency f, which frequency f. has a fixed relationship to the line frequency.

30 When recording, various switches are in the position marked with (REC). In these positions, an input 30 is supplied with a video signal, for example from a tuner 31 of a receiver, or from a camera, the filter color of which, in that case modulated with a carrier wave of frequency fs, is modulated with filter 32. 35 separate. This PAL color signal is supplied to input 50 via switch 27. Of the comb filter and mixing system behind input 50, only mixing stage 22 is used when recording, which modulates the PAL color signal to a carrier wave with a frequency of 8104101 J * PHN 10.152 14. and with which the cm to obtain the recording patterns according to figures 5 and 6 according to the correct pattern the PAL phase is inverted and the phase of the subcarrier is inverted. It can also be demonstrated for this that this can be done by using 5 mixing signals with the sum frequency (f + f.) And the difference frequency S 1 (f-f.) And their inverses, with the correct signals in the correct sequence in the same order. manner as in the case of reproduction are obtained via switch 38 and phase inverters 40a and 40b. The desired output from mixer 22 is separated with filter 24 and after further processing 10 is fed to a take-up head 26b, which may be the same as display head 26a. Furthermore, upon recording, the video signal applied to input 30 is applied via switch 34 to the pulse separation circuit 35 to recover the vertical and horizontal synchronization pulses. In the case of recording, pulse separation circuit 35 also supplies, via output 49, a 15 color burst pulse to a color burst shortcut 36 which, on the command of that "ΤΓ color burst pulse, separates the color burst - € B sin (wt + from the S" * ~ x PAL color signal). at the output of filter 32 and through switch 46 to the oscillator 45 in order to synchronize, using phase-locked loop techniques, the signal of frequency f with the color 20 burst which also shows a frequency fs.

With regard to the other line inverter and the phase of the subcarrier when reproduced with the aid of phase inverters 40a and 40b, it can be noted that this can be done by counting the lines with a counter, controlled by the line synchronizing pulses 25 output 48 of the impulse separation circuit 35. With the aid of logic the phase inversion of the carrier wave can then be controlled such that this phase is inverted the other line. During the tracks (B and 'D in figure 7) that no inversion takes place, this inverter must be interrupted, then H-alignments with positive or negative inferior value of n when counting, start with line A, an additional phase jump of 180 ° is always necessary at the beginning of track C (due to the odd number of lines per video image and the integer value of n). While it is easy to distinguish between tracks B and D on the one hand and tracks A and C on the other, because those 35 tracks are always read with the same of the two heads of a two-head recorder, it is not immediately possible to distinguish between tracks A and C in order to insert that extra phase inversion in the right place. A known method is to also count the tracks. 8104101 PHN 10.152 and to detect a possible erroneous start with a detection circuit and to pass the counters thereon. This correction is then made not only in case of an incorrect start, but also in the case of an incorrect inversion cycle due to malfunctions. A drawback of this method 5 is that an additional circuit is required for this and that this correction proves to be rather slow, so that an annoying disturbance in the color reproduction occurs for some time. A relatively simple method is based on the fact that in the situation according to figure 7 the phase inversion cycle has a fixed relationship just at the beginning of the track 10 and thus with the vertical synchronization pulse. By now always coupling the phase inversion cycle to the occurrence of the vertical synchronization pulse (with logic circuit 39 in figure 8) it can be achieved that the phase inversion cycle is correct at the beginning of each track A or C. Any disturbance is then always corrected within the duration of a video image, while no detection circuit is required to detect an erroneous phase inversion cycle. In the case of the non-integer H alignments n = + 3.5, +1.5, +2.5 ..., which situations for n = -0.5 and n = -1.5 in Figure 9 displayed, this solution is not entirely sufficient. Although in those situations when counting down the 20 lines it appears that the counting cycle continues without additional inversion from track A to track C (via track B with a blocked inversion cycle), when connecting the phase, measure inversion cycle a to the vertical Synchronization impulse is distinguished here between the tracks A and C, because the phase inversion cycle in track C is exactly the other way around with respect to the beginning of the track than when testing track A. However, a suitable track identification can be obtained when in the Tracks of low-frequency tracking signals have been recorded according to, inter alia, the system described in Dutch patent application no. 7702815 (PHN 8728), in which signals are recorded in four consecutive tracks with different frequencies per 30 track.

35 8104101

Claims (7)

1. PAL comb filter comprising a first and a second chain, input means for supplying a PAL color signal to both chains, a delay network for delaying the PAL color signal in the first chain with respect to the PAL color signal in the 5 th another circuit, and a signal combination circuit for combining the PAL color signal in the second chain with the correct mutual polarity and the PAL color signal delayed in the first chain, such that the signal generated by that combination is again a PAL color signal, characterized in that the delay network 10 has a time delay such that the PAL color signal in the first chain is delayed over the duration corresponding to a line of a video image relative to the PAL color signal in the second chain, and that PAL- phase inversion means are included for the inverter and of the PAL phase of the signal in either chain. PAL comb filter according to claim 1, in particular intended for a device for reproducing video signals which are recorded in adjacent tracks of a record carrier, characterized in that the PAL phase inversion means are designed to be controllable, such that the PAL phase inversion takes place on command of a control signal 20 either in the first chain or in the second chain. PAL comb filter according to claim 2, characterized in that the PAL phase inversion means a first switchable PAL phase inverter included in the first chain and a second switchable PAL phase inverter included in the second chain, comprising 25 control means for switching one of the two PAL phase inverters alternately on command of the control signal, PAL comb filter according to claim 1 or 2, for use in a PAL video system in which the PAL color signal with a first carrier frequency is transformed into a PAL color signal with a second carrier frequency, characterized in that the PAL phase inversion means include frequency mixing means for mixing the PAL color signal at a first carrier frequency with a signal having a frequency equal to the sum of the first and second carrier frequencies, such that mixing occurs in both chains of the comb filter. The PAL comb filter according to claim 3, for use in a PAL video system, wherein the PAL color signal is transformed with a first carrier 8104101 PHN 10.152 17 frequency into a PAL color signal with a second carrier frequency, characterized in that: that the first switchable PAL phase inverter comprises a first mixing stage and the second switchable PAL phase inverter comprises a second mixing stage for transforming the PAL color signal from the first carrier frequency to the second carrier frequency, and that the control means comprise a mixing signal. generator for the liver and comprising a first mixing signal with a frequency equal to the sum of the first and second carrier frequency and a second mixing signal with a frequency equal to the difference of the first 10 and second carrier frequency, and further comprising switching means which can be switched by means of the required control signal for springing into a first position and from the first mixing signal to the first mixing stage and the second mixing signal to the second mixing stage and in a second position supplying the second mixing signal to the first mixing stage and the first mixing signal to the second mixing stage. PAL comb filter according to claim 5, characterized in that between the mixing signal generator and the first mixing stage is a first switchable msng signal-phase inverter and between the mixing signal generator and the second mixing stage is a second switchable mixing signal phase inverter. 20 included to make the carrier phase of the PAL color signal reversible with the second carrier frequency. 7. PAL comb filter according to claim 5 or 6, for use in a video system in which the EAL color signal with the second carrier frequency is transformed to a PAL color signal with the first carrier frequency, for recording the video signals, characterized in that an output for drawing the PAL color signal at the second carrier frequency through a bandpass filter tuned to the second carrier frequency connected to an output of the second mixer. 30 35 8104101